Wrong result from scipy.optimize.minimize used on Fortran function using ctypes

I currently have a Fortran function that I want to optimize using SciPy wrapping it using Ctypes. Is this possible? Perhaps I've done something wrong in my implementation. For example, assume I have:

cost.f90

``````module cost_fn
use iso_c_binding, only: c_float
implicit none

contains

function sin_2_cos(x,y) bind(c)
real(c_float) :: x, y, sin_2_cos
sin_2_cos = sin(x)**2 * cos(y)
end function sin_2_cos

end module cost_fn
``````

that I compile with:

``````gfortran -fPIC -shared -g -o cost.so cost.f90
``````

and then try to find a (local) minimum with:

cost.py

``````#!/usr/bin/env python

from ctypes import *
import numpy as np
import scipy.optimize as sopt

cost.sin_2_cos.argtypes = [POINTER(c_float), POINTER(c_float)]
cost.sin_2_cos.restype = c_float

def f2(x):
return cost.sin_2_cos(c_float(x[0]), c_float(x[1]))
# return np.sin(x[0])**2 * np.cos(x[1])

# print(f2( [1, 1] ))
# print(f2( [0.5 * np.pi, np.pi] ))

print( sopt.minimize( f2, (1.0, 1.0), options={'disp': True}, tol=1e-8) )
``````

I expect a local minimum f2(pi / 2, pi) = -1. When I call f2 with the cost.sin_2_cos return value, the "minimimum" is just given at the initial guess of (1, 1). If I call f2 with the "Python" return value, optimize finds the correct minimum.

I've tried redefining sin_2_cos to take dimension(2) array input, but was seeing similar behavior. Perhaps I need to call sin_2_cos directly with minimize (but then how would I specify c_float for the arguments)? Any thoughts are appreciated!

Edit: To a comment below, note that the two commented `print(f2(...))` lines produce the expected values. Thus, I believe the Fortran function is being properly called through the Python f2 function.

• You must add at least (there might be other problems) the 'value' attribute to your arguments, see fortran90.org/src/best-practices.html#using-ctypes May 16 '17 at 20:58
• Why must I do this? If I uncomment the calls to f2, it works correctly. The webpage you listed doesn't make it clear why 'value' is there nor does it use it in the earlier `iso_c_binding` example. Note that adding value doesn't resolve the issue. May 16 '17 at 21:06
• I changed the title to something more specific. I assume "Yes, it can." would not be an acceptable answer for you. May 16 '17 at 21:13
• Have you checked that the function gives correct values when called from Python? May 16 '17 at 21:14
• When I uncomment the two `print(f2(...))` lines, I get the expected values (0.382573664188385 and -1.0) with the code I posted. May 16 '17 at 21:19

Your Fortran code uses single precision floating point values (i.e. 32 bit floats). (In C, `float` is single precision and `double` is double precision.) The default method used by `scipy.optimize.minimize()` uses finite differences to approximate the derivatives of the function. That is, to estimate the derivative `f'(x0)`, it computes `(f(x0+eps) - f(x0))/eps`, where `eps` is the step size. The default step size that it uses to compute the finite differences is approximately 1.49e-08. Unfortunately, this value is smaller than the spacing of single precision values around the value 1. So when the minimizer adds `eps` to 1, the result is still 1. That means the function is evaluated at the same point, and the finite difference result is 0. That's a condition for the minimum, so the solver decides it is done.

The solver option `eps` sets the finite difference step size. Set it to something larger than 1.19e-7. For example, if I use `options={'disp': True, 'eps': 2e-6}`, I get a solution.

By the way, you can find that value, 1.19e-7, by using `numpy.finfo()`:

``````In [4]: np.finfo(np.float32(1.0)).eps
Out[4]: 1.1920929e-07
``````

You'll also get a solution if you use the option `method='nelder-mead'` in the `minimize()` function. That method does not rely on finite differences.

Finally, you could convert the Fortran code to use double precision:

``````module cost_fn
use iso_c_binding, only: c_double
implicit none

contains

function sin_2_cos(x,y) bind(c)
real(c_double) :: x, y, sin_2_cos
sin_2_cos = sin(x)**2 * cos(y)
end function sin_2_cos

end module cost_fn
``````

Then change the Python code to use `ctypes.c_double` instead of `ctypes.c_float`.

• Excellent, thank you for the clear explanation and two alternative solutions. I can confirm that both approaches work and I've accepted your solution. Interestingly, I looked through the scipy.optimize.minimize documentation but couldn't find the `eps` argument so I didn't identify that as a cause. May 17 '17 at 13:31
• I should have added to the prior comment that I looked at the base documentation but didn't dive into the method-specific documentation. Had I done so, I would have come across `eps`. However, focusing on this level of detail removes some of the abstraction of just calling `minimize`. Hopefully future readers can learn from my mistake / lack of diligence. May 17 '17 at 13:43